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胡鋼

(哈爾濱工業大學(深圳)教授/博士生導師)

鎖定
胡鋼,哈爾濱工業大學(深圳)土木與環境工程學院教授,博士生導師,國家級青年人才。2015年畢業於香港科技大學獲得土木工程博士學位,並於澳大利亞悉尼大學從事博士後研究。主要採用人工智能技術、風洞試驗技術和計算流體動力學進行空氣動力學、結構風工程、環境風工程和風能相關的研究。至今共發表SCI國際期刊論文100餘篇,其中JCR一區論文80餘篇,ESI高被引和熱點文章2篇。主持國家重點研發計劃課題1項,國家自然科學基金面上項目和青年項目各1項,深圳市海外高層次人才項目1項;作為核心成員參與 1 項澳大利亞國家基金委項目、多項香港政府研究資助局項目、國家自然科學基金委項目、深圳市孔雀團隊項目。擔任中國土木工程學會橋樑及結構分會風工程學術委員會委員,全國抗風減災與風能利用專委會委員,智能流體力學執行委員會執行委員,香港風工程協會秘書兼執行委員,澳大利亞風工程協會會員,美國土木工程師協會會員,國際期刊Advances in Structural Engineering青年編委。受邀參加第17屆意大利全國風工程會議作大會主旨報告,入選斯坦福大學全球前2%頂尖科學家“2022年度影響力”排行榜。 [1] 
中文名
胡鋼
國    籍
中國
民    族
出生地
江西
畢業院校
香港科技大學
學位/學歷
博士
職    業
教師
專業方向
土木工程

目錄

  1. 1 人物經歷
  2. 2 研究方向
  3. 3 社會任職
  4. 4 主要作品

胡鋼人物經歷

2021-至今:教授,博導,土木與環境工程學院,哈爾濱工業大學(深圳)
2019-2020:副教授,土木與環境工程學院,哈爾濱工業大學(深圳)
2017-2019:博士後, 土木工程學院, 悉尼大學, 澳大利亞
2016-2017:博士後, 土木與環境工程學院, 香港科技大學
2015-2016:副研究員, 中電風洞實驗室, 香港科技大學

胡鋼研究方向

  1. 機器學習和人工智能技術在土木工程中的應用
  2. 機器學習和人工智能技術在空氣動力學和流體力學中的應用
  3. 高層建築、高聳結構和大跨度結構的抗風性能評估和風振控制
  4. 風洞試驗技術和計算流體動力學模擬技術的應用和開發
  5. 風能評估和風電場選址
  6. 城市風環境的評估和優化

胡鋼社會任職

2023-至今, 委員, 中國土木工程學會橋樑及結構分會風工程學術委員會
2023-至今, 委員, 全國抗風減災與風能利用專委會
2023-至今, 委員, 智能流體力學執行委員會
2022-至今, 青年編委, Advances in Structural Engineering
2020-至今, 秘書, 香港風工程協會
2018-至今, 會員, 澳大利亞風工程協會
2016-至今, 執行委員, 香港風工程協會

胡鋼主要作品

[1]. Hu, G., Liu, L., Tao, D., Song, J., Tse, K.T., Kwok, K.C.S., 2020. Deep learning-based investigation of wind pressures on tall building under interference effects. Journal of Wind Engineering and Industrial Aerodynamics, 201, 104138.
[2]. Hu, G., Kwok, K. C. S. (2020). Predicting wind pressures around circular cylinders using machine learning techniques. Journal of Wind Engineering and Industrial Aerodynamics, 198, 104099.
[3]. Chao Li, Jinghan Wang, Hu, G., Lixiao Li, Yiqing Xiao, 2020. RANS simulation of horizontal homogeneous atmospheric boundary layer over rough terrains by an enriched canopy drag model, Journal of Wind Engineering and Industrial Aerodynamics, 206, 104281.
[4]. Cruz Y. Li, Tim K.T. Tse, Hu G., 2020, Dynamic Mode Decomposition on pressure flow field analysis: Flow field reconstruction, accuracy, and practical significance, Journal of Wind Engineering and Industrial Aerodynamics, 205, 104278.
[5]. H.Y. Peng, S.F. Dai, K. Lin, Hu G., H.J. Liu, 2020, Experimental investigation of wind characteristics and wind energy potential over rooftops: Effects of building parameters, Journal of Wind Engineering and Industrial Aerodynamics, 205, 104304.
[6]. K.T. Tse, A.U. Weerasuriya, Hu G., 2020 Integrating topography-modified wind flows into structural and environmental wind engineering applications, Journal of Wind Engineering and Industrial Aerodynamics, 204, 104270.
[7]. Hu, G., Fengxi Liu, Lixiao Li, Chao Li, Yiqing Xiao, and Kwok, K. C. S., 2019, Wind energy harvesting performance of tandem circular cylinders with triangular protrusions, Journal of Fluids and Structures, 91, 102780.
[8]. Hu, G., Junlei Wang, Zhen Su, Guoping Li, Huayi Peng and K.C.S. Kwok, 2019, Performance evaluation of twin piezoelectric wind energy harvesters under mutual interference, Applied Physics Letters, 115, 073901.
[9]. Hu, G., Jie Song, Sina Hassanli, Robert Ong, and Kwok, K. C. S., 2019, The effects of a double-skin facade on the cladding pressure around a tall building. Journal of Wind Engineering and Industrial Aerodynamics. 191, 239-251.
[10]. Weiwei Song, Liang, S., Song, J., Lianghao Zou, Hu, G., 2019. Investigation on wind-induced aero-elastic effects of tall buildings by wind tunnel test using a bi-axial forced vibration device. Engineering Structures. 195, 414-424.
[11]. Chao Zhang, Junhong Zhao, Hu, G., Maoling Shi, Xueguan Song, Dacheng Tao, and Wei Wu, 2019. A Data-Driven Framework for Tunnel Geological-Type Prediction Based on TBM Operating Data. IEEE Access. 7, 66703-66713.
[12]. Cui, D., Hu, G., Ai, Z., Du, Y., Mak, C.M., Kwok, K.C.S., 2019. Particle image velocimetry measurement and CFD simulation of pedestrian level wind environment around U-type street canyon. Build. Environ. 154, 239–251.
[13]. Jie Song, Wei Xu, Hu, G., Shuguo Liang, Jian Tan, 2019, Non-Gaussian properties and their effects on extreme values of wind pressure on the roof of long-span structures. Journal of Wind Engineering and Industrial Aerodynamics. 184, 106-115.
[14]. Hu, G., Tse, K.T., Wei, M., Naseer, R., Abdelke, A., Kwok, K.C.S., 2018, Experimental investigation on the efficiency of circular cylinder-based wind energy harvester with different rod-shaped attachments. Applied Energy 226, 682–689.
[15]. Hu, G., C. Li, K. T. Tse, and K. C. S. Kwok, 2018, Vortex induced vibration of an inclined finite-length square cylinder, European Journal of Mechanics - B/Fluids, 68, 144–152.
[16]. Sina Hassanli, Hu G., David F. Fletcher, Kwok, K.C.S., 2018, Potential Application of Double Skin Facade Incorporating Aerodynamic Modifications for Wind Energy Harvesting, Journal of Wind Engineering and Industrial Aerodynamics. 174, 269-280.
[17]. Song Jie, Tse K.T., Hu G., Liang S, Zou L., 2018, Dynamic properties of wind-excited linked tall buildings considering both intra- and inter-building structural couplings. Journal of Structure Engineering, ASCE. 2018;144(6017007):1-11.
[18]. Chao Li, Yiqing Xiao, You-lin Xu, Yi-xin Peng, Hu, G. and Songye Zhu, 2018, Optimization of Blade Pitch in H-rotor Vertical Axis Wind Turbines through Computational Fluid Dynamics Simulations, Applied Energy, 212, 1107-1125.
[19]. Liang, S., Yang, W., Song, J., Wang, L., Hu, G., 2018. Wind-induced responses of a tall chimney by aeroelastic wind tunnel test using a continuous model. Engineering Structures 176, 871–880.
[20]. Hu, G., K. T. Tse, Z. S. Chen, and Kwok, K.C.S., 2017, Particle Image Velocimetry measurement of flow around an inclined square cylinder, Journal of Wind Engineering and Industrial Aerodynamics. 168, 134-140.
[21]. Hu, G., Sina Hassanli, Kwok, K.C.S., and Tse, K.T., 2017, Wind-induced responses of a tall building with a double-skin fa?ade system. Journal of Wind Engineering and Industrial Aerodynamics. 168, 91–100.
[22]. Hu, G., K.T. Tse, Song Jie, and Liang S.G., 2017, Performance of wind-excited linked building systems considering the link-induced structural coupling. Engineering Structures, 138, 91-104.
[23]. Wei M. H., Hu, G., Li L. X., Liu H. T., 2017, Development and theoretically evaluation of an STF–SF isolator for seismic protection of structures. Meccanica. doi:10.1007/s11012-017-0785-z.
[24]. Sina Hassanli, Hu, G., K. C. S. Kwok, David F. Fletcher, 2017, Utilizing Cavity Flow within Double Skin Fa?ade for Wind Energy Harvesting in Buildings, Journal of Wind Engineering and Industrial Aerodynamics. 167, 114–127.
[25]. Song Jie, Hu, G., Tse, K.T., Li, S.W., Kwok, K.C.S, 2017, Performance of a circular cylinder piezoelectric wind energy harvester fitted with a splitter plate, Applied Physics Letters. 111(22):223903.
[26]. Z. S. Chen, K. T. Tse, Hu, G., and K. C. S. Kwok, 2017, Experimental and theoretical investigation of galloping of transversely inclined slender prisms, Nonlinear Dynamics.
[27]. Wei, M.H., Sun, L., Hu, G., 2017, Dynamic properties of an axially moving sandwich beam with MRF core, Advances in Mechanical Engineering. Vol. 9(2) 1–9.
[28]. Li, S.W., Hu, Z.Z., Chan, P.W., and Hu, G., 2017, A study on the profile of the turbulence length scale in the near-neutral atmospheric boundary for sea (homogeneous) and hilly land (inhomogeneous) fetches. Journal of Wind Engineering and Industrial Aerodynamics. 168, 200-210.
[29]. Zhou Shengtao, Shan Baohua, Xiao Yiqing, Li Chao, Hu, G., Song Xiaoping, Liu Yongqing, Hu Yimin, 2017, Directionality Effects of Aligned Wind and Wave Loads on a Y-Shape Semi-Submersible Floating Wind Turbine under Rated Operational Conditions. Energies 10(12):2097.
[30]. Li C, Zhuang T, Zhou S, Xiao Y. Q., and Hu, G., 2017, Passive Vibration Control of a Semi-Submersible Floating Offshore Wind Turbine, Applied Sciences. 7 1–19.
[31]. Chen, Z.-S, Zhou, J.-T., Hu, G., Li, Y., Ma, H. Yao, G.-W., 2017, A novel movable scaffolding system (MSS) for a long-span curved girder bridge, International Journal of Robotics and Automation, 32, 2, 164-175.
[32]. Hu, G., Tse, K.T., Kwok, K.C.S, Song Jie, and Lyu Yuan. 2016, Aerodynamic modification to a circular cylinder to enhance piezoelectric wind energy harvesting, Applied Physics Letters. 109(19), 193902.
[33]. Hu, G., Tse, K.T., and Kwok, K.C.S. 2016, Enhanced performance of wind energy harvester by aerodynamic treatment of a square prism, Applied Physics Letters. 108(12), 123901.
[34]. Hu, G., Tse, K.T., Kwok, K.C.S., 2016. Aerodynamic mechanisms of galloping of an inclined square cylinder. Journal of Wind Engineering and Industrial Aerodynamics. 148, 6-17.
[35]. Wei, M.H., Hu, G., Jin, L., Lin, K. and Zou, D. 2016, Forced vibration of a shear thickening fluid sandwich beam, Smart Materials and Structures. 25(5), 055041.
[36]. Chen, Z., Zhou, J., Tse, K.T., Hu, G., Li, Y. and Wang, X. 2016, Alignment control for a long span urban rail-transit cable-stayed bridge considering dynamic train loads, Science China Technological Sciences. 59(11), 1759-1770.
[37]. Hu, G., Tse, K.T., Kwok, K.C.S., Chen Z.S., 2015. Pressure measurements on inclined square prisms. Wind and Structures, 21, 383-405.
[38]. Hu, G., Tse, K.T., Kwok, K.C.S. and Zhang, Y., 2015. Large eddy simulation of flow around inclined finite square cylinders, Journal of Wind Engineering and Industrial Aerodynamics. 146, 172-184.
[39]. Hu, G., Tse, K.T. and Kwok, K.C.S., 2015. Galloping of forward and backward inclined slender square cylinders, Journal of Wind Engineering and Industrial Aerodynamics. 142, 232-245.
[40]. Li, Q.S., Hu, G., Yan, Bo-wen, 2014. Investigation of the effects of free-stream turbulence on wind-induced responses of tall building by large eddy simulation. Wind and Structures 18, 599-618.
參考資料